242 3 Quantum Mechanics – II
But the total cross-section is given byσt=4 π
k^2(2l+1) sin^2 δl.It follows thatIm f(0)=kσt/ 4 π. The last equation is known as the opti-
cal theorem.3.116 V(r)=
(
−
Ze^2
2 R)(
3 −
r^2
R^2)
;0<r<R (1)=−
Ze^2 e−ar
r;R<r<∞ (2)Inside the nucleus the electron sees the potential as given by (1) corre-
sponding to constant charge distribution, while outside it sees the shielded
potential given by (2). The scattering amplitude is given byf(θ)=−(2μ/q^2 )∫∞
0V(r)rsin(qr)dr= 2 μZe^2
q^2[(
1
2 R
)∫ R
0(
3 −
r^2
R^2)
rsin(qr)dr+∫∞
Rsin(qr)e−ardr]
(3)
The first integral is easily evaluated and the second integral can be written
as
∫∞Rsin(qr)e−ardr=∫∞
0sin(qr)e−ardr−∫ R
0sin(qr)e−ardr (4)=
q
q^2 +a^2−
∫R
0sin(qr)e−ardr (5)(Lima→0)=1
q−
∫R
0sin(qr)dr=1
qcos(qr)We finally obtainf(θ)=(
−
2 μZe^2
q^2 ^2)(
3
q^2 R^2)(
sin(qR)
qR−cosqR)
σ(θ)finite size=σ(θ)point charge|F(q)|^2
where the form factor is identified asF(q)=(
3
q^2 R^2)(
sin(qR)
qR−cos(qR))
The angular distribution no longer decreases smoothly but exhibits sharp
maxima and minima reminiscent of optical diffraction pattern from objects
with sharp edges. The minima occur whenever the condition tanqR=qR,
is satisfied. This feature is in contrst with the angular distribution from a
smoothly varying charge distribution, such as Gaussian, Yakawa, Wood-
Saxon or exponential, wherein the charge varies smoothly and the maxima